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Modular 3D Printed RC Car

I am a high school student and for my Christmas, I 3D printed my brother the Flutter Scout car. It is a remote control car that is entirely 3D printed. The following link has it's GitHub page with its parts and information about it: https://github.com/tlalexander/Flutter-Scout. This car was the inspiration for my project. The problem with this car was my middle school brother with ADD did not have the attention span to put it together and he could not keep track of all the parts. So I look for other models that had easier assembly.

I looked at OpenRC cars on Thingiverse. However, many required lots of non printed parts and importantly were not easily assembled. This project for me was about making something I could assemble with my younger brother without him losing focus.

So, I have designed a car that has several modules and combinations it can be assembled in. Currently, there are two gearbox designs, one steering assembly, and several types of tires. I have also tried to make it possible to easily add a body to the car, which I intend to design and upload soon.

Each step has attached the assembly instructions and the corresponding parts with technical drawings.

I would love to receive input from you guys and see any designs for bodies and other parts you have for the car. I would love to try them out.

If you like this project please vote for it in the Make it Move contest.

Step 3: Spur Gear Gearbox

All of the parts are available below. The back axle is the same back axle used in the other gear box.

1:10 Gear Ratio has A Gears

fast but may require a push

1:20 Gear Ratio has B Gears

untested

First screw the metal motor mount onto the brushless motor. It is X-shaped and will help keep the motor in place.

Print the 5-tooth spur gear.

Print Settings:

0.3 mm layer height

215 C

100% infill

Find the propeller adapter and place the retaining ring and then the 5-tooth spur gear on it.

Secure the adapter to the motor by screwing down the nut.

Place the motor into the slot on the side of the gearbox.

Locate the rafts printed earlier or a thin piece of cardboard or wood. Cut the rafts so they fit into the slot, but are still removable.

You might need to use more than one so the motor is secure. If you use more than one, I recommend hot gluing them together.

Print the middle axle, the 22 tooth large gear, and the A1 or B1 spur gear.

Axle Print Settings:

0.3 mm layer height

215 C

100% infill

Raft

30 mm/s print speed

Gear Print Settings:

0.3 mm layer height

215 C

100% infill

If time is a constraint:

50% infill

3 mm walls

These will wear out quicker, but are good for testing.

You should be able to pressure fit both gears onto the axle.

It might be necessary to use a hammer or to widen the hole on the gears. However, the gears need to have a tight fit on the axle.

If the gears are loose, print a scaled up version of the axle.

I plan on designing an axle with notches and clips that hold the axle in place, however until then, I recommend either hot gluing the gears and axle at a low temperature (compatible with ABS or PLA) or using super glue (compatible with PLA). The hot glue should be able to be peeled off if you want to change the gears and the super glue can be dissolved with acetone.

Place a bearing on either side of the axle.

Spread the gearbox apart and place the axle in the holes closest to the motor.

Print the A2 or B2 spur gear and back axle.

Axle Print Settings:

0.3 mm layer height

215 C

100% infill

Raft

Support touching build plate

30 mm/s print speed

Gear Print Settings:

0.3 mm layer height

215 C

100% infill

If time is a constraint:

50% infill

3 mm walls

These will wear out quicker, but are good for testing.

Following the same steps as the middle axle, secure the 50-tooth spur gear to the back axle.

Place bearings on either side of the axle.

Spread apart the gearbox and place the axle in the holes furthest from the motor.

Step 4: Worm Gear Gearbox

This gearbox is more difficult to assemble. It has a 60:1 gear ratio and the gears were modified from the McMaster-Carr component library on Autodesk Fusion 360.

All the parts are available below, the back axle is the same back axle used in the other gearbox.

First screw the X-shaped metal motor mount onto the brushless motor.

Print the 30-tooth gear and back axle.

Axle Print Settings:

0.3 mm layer height

215 C

100% infill

Raft

Support touching build plate

30 mm/s print speed

Gear Print Settings:

0.3 mm layer height

215 C

100% infill

If time is a constraint:

50% infill

3 mm walls

These will wear out quicker, but are good for testing.

Pressure fit the 30-tooth gear onto the back axle.

It might be necessary to widen the gear's hole if it is tight. If it is loose the back axle should be scaled up so it fits. You should use a hammer to fit the gear.

You should hot glue the gear in place at a low temperature (if using PLA or ABS) or use super glue (only if using PLA). The super glue can be dissolved later with acetone and the hot glue can be removed. If the hot glue is too hot, it will melt the gear or axle making removal harder.

Place bearings on either side of the axle.

Print the worm gear.

Print Settings:

0.1 mm layer height

215 C

100% infill

Raft

Support everywhere

30 mm/s print speed

If you have 2 extruders and easily soluble support filament I encourage you to use it.

Clean support of the worm gear thoroughly.

It needs to sit flat on the retaining ring and mesh easily with the 30-tooth gear.

Locate the propeller adapter and place the retaining ring and then worm gear on it.

To ensure a proper fit between the worm gear and the 30-tooth gear, you might need to add spacers to move the worm gear up along the propeller adapter.

Secure the worm gear by placing the propeller adapter on the motor shaft and tightening the nut.

Place the motor with the worm gear attached into the slot at the front of the gear box.

Cut rafts or thin pieces of cardboard or wood so they fit into the slot.

If using more than one glue them together to allow easier removal.

The rafts should be about 5 mm high than the gearbox so they can be removed if necessary.

Attachments

Step 8: Final Remarks

I feel the car I designed has improved on many features of the car I made my brother.

Having a 3-sided gear box allows for easy placement of the axles and larger gears. It also remains strong given the opposing forces created by the axles and front chassis.

The easily breakable steering pins have been replaced with screws.

The wheels are fully 3D printed and have built in suspension.

You can easily change the gearing.

Overall, there are less parts to assemble and assembly is quick.

The front chassis and it's connection to the gearbox are very strong.

However, there are some places where my car falls short.

Some parts are harder to fit together and require the use of a hammer or the removal of material.

Some parts need to be glued together instead of using grooves and clips to be secured.

There is no place for the electronic components.

The worm gear gearbox has issues with getting jammed and keeping the gears engaged with each other.

It uses some parts that are not easily accessible like the propeller adapters.

Some tires require rubber bands to be placed around them to gain sufficient traction.

The worm gear gearbox had very slow acceleration and seemed to struggle getting started. However, after starting it runs fairly smoothly.

The worm gear slipped a lot.

None of the current tires work well on grass or ice.

The spur gear gearbox sometimes requires a push to get it started.

The spur gear gearbox is sometimes uncontrollable.

Things in the works

I am working on a body for it that will be placed in the top slot on the side that articulates with the front chassis.

I am designing my own steering arm and will update the steering assembly by August.

I plan to design a low gear box that allows for smaller tires.

I will create some new tire designs that work better off of pavement.

I am drafting a new instructable on how I designed the car.

I would enjoy seeing pictures of peoples cars that they print and any suggestions or help in modifying the parts I have now. I also would greatly appreciate the creation of new modules that might allow for things like better handling or more speed. I am curious to see what body designs are created as well.

I will upload technical drawings to this step as they are completed so people can modify and create their own modules.

If there is any other information needed place it in the comments below.

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6 Discussions

First, I am so impressed you would do this for your brother. It can be hard to be patient with kids who have ADD and I applaud you and your parents for working on an affectionate, functional relationship! Your brother is a very lucky young man. Second, this car is awesome! My very young grandson is a car freak, and I would love to make this on my brother's 3D printer, which he is unfortunately cannabalizing for his newest wonderful machine (I think a CDC router). Shoot!

You could possibly use it. I could give a more definitive answer if you uploaded a picture of what the receiver looks like. Some have the ESC built into the receiver's circuit board, in which case you could not use it. But, if you can easily find the servo wires connecting the servo motor and the ESC to the receiver you could use it.

For a body design, I think the existing form would look good with a squatty model A "ratrod" sort of body, keeping the electronics exposed in the area in front of what looks like a firewall. A little grill in front would finish it off nicely too! Here's a quick sketch I made: